Look at brief notes of Function Overloading.You can view tutorialfocus.net to get complete explanation of topic with its programs.

1. FUNCTION
OVERLOADING
1 Ritika sharma

2. Polymorphism
The word polymorphism is derived from Greek word Poly
which means many and morphos which means forms.
Polymorphism can be defined as the ability to use the same
name for two or more related but technically different tasks.
Eg-woman plays role of daughter,sister,wife,mother etc.
2 Ritika sharma

3. Overloading in C++
What is overloading
– Overloading means assigning multiple
meanings to a function name or operator
symbol
– It allows multiple definitions of a function with the same
name, but different signatures.
C++ supports
– Function overloading
– Operator overloading
3 Ritika sharma

4. Why is Overloading Useful?
 Function overloading allows functions that
conceptually perform the same task on
objects of different types to be given the
same name.
 Operator overloading provides a convenient
notation for manipulating user-defined
objects with conventional operators.
4 Ritika sharma

5. Function Overloading
Is the process of using the same name for two or more
functions
Requires each redefinition of a function to use a different
function signature that is:
different types of parameters,
or sequence of parameters,
or number of parameters
Is used so that a programmer does not have to remember
multiple function names
5 Ritika sharma

6. Function Overloading
Two or more functions can have the same name but different
parameters
Example:
int max(int a, int b)
{
if (a>= b)
return a;
else
return b;
}
float max(float a, float b)
{
if (a>= b)
return a;
else
return b;
}
6 Ritika sharma

7. Overloading Function Call Resolution
 Overloaded function call resolution is done by
compiler during compilation
– The function signature determines which definition
is used
 a Function signature consists of:
– Parameter types and number of parameters
supplied to a function
 a Function return type is not part of function signature
and is not used in function call resolution
7 Ritika sharma

8. void sum(int,int);
void sum(double,double);
void sum(char,char);
void main()
{
int a=10,b=20 ;
double c=7.52,d=8.14;
char e=‘a’ , f=‘b’ ;
sum(a,b); //calls sum(int x,int y)
sum(c,d); //calls sum (double x,double y)
sum(e,f); // calls sum(char x,char y)
}
void sum(int x,int y)
{
vout<<“n sum of integers are”<<x+y;
}
void sum(double x,double y)
{
cout<<“n sum of two floating no are”<<x+y;
}
void sum(char x,char y)
{
cout<<“n sum of characters are”<<x+y;
8 Ritika sharma

9. Output:
Sum of integers 30
sum of two floating no are 15.66
sum of characters are 195
9 Ritika sharma

10. Void area(int)
Void area(int,int);
Void area(int,int,int);
Int main()
{
Int side=10,le=5,br=6,a=4,b=5,c=6;
Area(side);
Area(le,br);
Area(a,b,c);
Getch();
Return 0;
}
Void area(int x)
{ cout<<“area is”<<x*x;
}
Void area(int x,int y)
{cout<<“area of rectang;e”=<<x*y;
}
Void area(int x,int y,int z)
{cout<<“volume is”<<x*y*z;
}
10 Ritika sharma

11. Function Selection Involves following
Steps.
Compiler first tries to find the Exact match in which the type
of argument are the same,and uses that func.
If an exact match is not found,the compiler user the integral
promotions to the actual argument such as,char to int, float
to double.
When either of them fails ,build in conversions are
used(implicit conversion) to the actual arguments and then
uses the function whose match is unique.but if there are
multiple matches,then compiler will generate an error
message.
11 Ritika sharma

12. For ex: long square(long n)
long square(double x)
Now a func. call such as square(10) will cause an
error because int argument can be converted into
long also and double also.so it will show
ambiguity.
User defined conversion are followed if all the
conversion are failed.
12 Ritika sharma

13. SCOPE RULES
13 Ritika sharma

14. Scope
The scope of a variable is the portion of a program where the
variable has meaning (where it exists).
A global variable has global (unlimited) scope.
A local variable’s scope is restricted to the function that
declares the variable.
A block variable’s scope is restricted to the block in which
the variable is declared.
14 Ritika sharma

15. Understanding Scope
Some variables can be accessed throughout an entire
program, while others can be accessed only in a limited part
of the program
The scope of a variable defines where it can be accessed in a
program
To adequately understand scope, you must be able to
distinguish between local and global variables
15 Ritika sharma

16. Local variables
Parameters and variables declared inside the definition of a
function are local.
They only exist inside the function body.
Once the function returns, the variables no longer exist!
That’s fine! We don’t need them anymore!
16 Ritika sharma

17. Block Variables
You can also declare variables that exist only within the body
of a compound statement (a block):
{
int foo;
…
…
}
17 Ritika sharma

18. Global variables
You can declare variables outside of any function definition –
these variables are global variables.
Any function can access/change global variables.
Example: flag that indicates whether debugging information
should be printed.
18 Ritika sharma

19. Distinguishing Between Local
and Global Variables
Celebrity names are global because they are known to people
everywhere and always refer to those same celebrities
Global variables are those that are known to all functions in a
program
Some named objects in your life are local
You might have a local co-worker whose name takes
precedence over, or overrides, a global one
19 Ritika sharma

20. A note about
Global vs. File scope
A variable declared outside of a function is available
everywhere, but only the functions that follow it in the file
know about it.
The book talks about file scope, I’m calling it global scope.
20 Ritika sharma

21. Block Scope
int main(void) {
int y;
{
int a = y;
cout << a << endl;
}
cout << a << endl;
}
Error – a
doesn’t exist outside
the
block!
21 Ritika sharma